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| United States Patent |
5,311,540
|
|
Pocholle
, et al.
|
May 10, 1994
|
Laser with coupled optical waveguides
Abstract
The invention relates to lasers, and more particularly to solid state
lasers such as neodymium on lithium niobate crystal lasers. The invention
provides a structure with several juxtaposed optical waveguides (12)
sufficiently close to each other laterally to be coupled laterally. In
order to take into account the risks of inhomogeneity in the refractive
indices or inaccuracies in the dimensions which would alter the
distribution of the electromagnetic field of the propagation supermode in
the coupled structure, it is proposed to act on the value of the index of
propagation in each guide using an individual control (generally
electrical). Because of the variation in index, individually controlled,
phase differences in the laser wave between the different guides are
produced and these phase differences react on the composition of the
electromagnetic field defining the supermode. It is possible to go as far
as modifying the directivity of the laser beam by this electrical control.
The control is preferably achieved by electrodes (14) placed in the
vicinity of each guide. The guides are made of an electro-optical material
such as lithium niobate, and neodymium doping, for example, allows the
laser effect to appear in the very interior of the guides.
| Inventors:
|
Pocholle; Jean-Paul (Arpajon/La Norville, FR);
Lallier; Eric (Levallois, FR);
Papuchon; Michel (Villebon, FR)
|
| Assignee:
|
Thomson Composants Militaires et Spatiaux (Courbevoie, FR)
|
| Appl. No.:
|
849077 |
| Filed:
|
April 28, 1992 |
| PCT Filed:
|
September 10, 1991
|
| PCT NO:
|
PCT/FR91/00715
|
| 371 Date:
|
April 28, 1992
|
| 102(e) Date:
|
April 28, 1992
|
| PCT PUB.NO.:
|
WO92/04748 |
| PCT PUB. Date:
|
March 19, 1992 |
Foreign Application Priority Data
| Current U.S. Class: |
372/97; 372/23; 372/50.1; 372/70; 372/71; 385/3 |
| Intern'l Class: |
H01S 003/082 |
| Field of Search: |
372/71,70,92,50,97,23,6
385/1,2,3
|
References Cited
U.S. Patent Documents
| 3725809 | Apr., 1973 | Ulrich et al. | 372/94.
|
| 4714312 | Dec., 1987 | Thaniyavarn | 385/3.
|
| 4763975 | Aug., 1988 | Scifres et al. | 385/15.
|
| 4878724 | Nov., 1989 | Thaniyavarn | 385/3.
|
| 5121400 | Jun., 1992 | Verdiell et al. | 372/97.
|
| Foreign Patent Documents |
| 2095419 | Sep., 1982 | GB.
| |
Other References
SPIE, vol. 1131, Optical Space Communication, Paris, Apr. 24-26, 1989, E.
Lallier et al.: "Towards a laser diode pumped Nd:LiNbO3 waveguide laser",
pp. 247-251.
|
Primary Examiner: Epps; Georgia Y.
Attorney, Agent or Firm: Oblon, Spivak, McClelland, Maier & Neustadt
Claims
We claim:
1. A laser device for providing a desired coherent light output,
comprising:
a substrate comprising a solid material, wherein said solid material is
capable of stimulated emission of light in response to optical excitation;
a plurality of optically coupled juxtaposed optical waveguides, each
waveguide having refractive indices, wherein said waveguides are formed in
said solid material;
a source of light energy oriented to direct light energy emitted therefrom
toward said solid material; and
means for individually controlling the refractive indices of different ones
of the waveguides so as to control phase relationships of stimulated
emission between different ones of the waveguides.
2. A laser structure according to claim 1, wherein:
said solid material is electrooptically active,
wherein said means for controlling comprises control electrodes for
applying voltages to said electrooptically active solid material,
wherein each of said control electrodes is disposed on said
electrooptically active solid material and each of said control electrodes
is disposed adjacent to at least one of said waveguides, and
wherein said laser structure further comprises means for applying voltages
to at least some of said control electrode, whereby said phase
relationships are adjusted.
3. A laser device according to claim 1, wherein said solid material
comprises a crystalline material selected from a member of the group
consisting of lithium niobate and lithium tantalate.
4. A laser device according to one of claims 1, 2 and 3, wherein said
substrate material is doped with neodymium.
5. A laser device according to claim 2, wherein at least one of said
control electrodes is placed on the substrate directly above a
corresponding one of said waveguides.
6. A laser device according to claim 2, wherein at least one of said
control electrodes is placed on the substrate between two adjacent ones of
said waveguides.
7. A laser device according to one of claims 1 and 2 wherein plane mirrors
are placed at two opposite ends of said substrate.
8. A laser device according to one of claims 1 and 2, further comprising:
at least one distributed reflecting lattice, wherein said distributed
reflecting lattice is formed in the substrate near one end of the
substrate.
9. A laser device according to one of claims 1 and 2, wherein:
an optical cavity includes at least part of the substrate and the optical
cavity is formed between first and second reflecting means, the first and
second reflecting means being separated from one another by a first
distance, and
wherein some of the waveguides have a length that is less than said first
distance.
10. A laser device according to one of claims 1 and 2, wherein said source
of light energy comprises a semiconductor laser.
11. A laser device according to claim 10, wherein an optical transfer
system is provided between said semiconductor laser and said plurality of
waveguides, for transferring light from said semiconductor laser to said
plurality of waveguides.
12. A method for making a laser device for providing a desired coherent
light output, comprising the steps of:
forming a substrate comprising a solid material, wherein said solid
material is capable of stimulated emission of light in response to optical
excitation;
forming in said solid material, a plurality of optically coupled juxtaposed
optical waveguides, each waveguide having refractive indices;
orienting a source of light energy so that light energy produced by the
source of light energy is directed toward said solid material; and
producing control electrodes near the waveguides wherein said control
electrodes can individually control the refractive indices of different
ones of the waveguides so as to control phase relationships of stimulated
emission between different ones of the waveguides.
13. A method for using a laser device for providing a desired coherent
light output, said laser device comprising a substrate comprising a solid
material, wherein said solid material is capable of stimulated emission of
light in response to optical excitation, a plurality of optically coupled
juxtaposed optical waveguides, each waveguide having refractive indices,
wherein said waveguides are formed in said solid material, a source of
light energy oriented to direct light energy emitted therefrom toward said
solid material, and means for individually controlling the refractive
indices of different ones of the waveguides so as to control phase
relationships of stimulated emission between different ones of the
waveguides, comprising the steps of:
emitting light energy from said source of light energy to thereby cause
stimulated emission of light in said solid material;
individually controlling the refractive indices of different ones of the
waveguides to thereby control said phase relationships.
Description
BACKGROUND OF THE INVENTION
The invention relates to coherent optical sources, particularly solid state
lasers.
Lasers operating on the principle of a structure with multiple parallel
optical waveguides coupled laterally with each other (multiple optical
waveguide structure) have already been devised.
In these structures, if the optical waveguides are placed side by side,
very close to each other, there is a mutual coupling of the optical wave
travelling in one guide with the optical wave of neighbouring guides. It
is therefore possible by making use of the mutual coupling between guides,
i.e. in practice by correctly choosing the distances between neighbouring
guides, to obtain at the output optical waves that are coherent, with a
distribution of electric field, and therefore of light energy, which is
not the simple superposition of the electric fields produced in each guide
but which is a composition corresponding to a mode of propagation
characteristic of the multiple guide structure.
Consequently, whereas uncoupled juxtaposed guides would lead to a
distribution of light energy distributed uniformly between the outputs of
the different guides, mutual optical coupling can lead to a non-uniform
energy distribution, possibly concentrated at the centre, for example with
a shape that is approximately Gaussian. Such a structure is thus very
worthwhile since it enables the energy from a spatially distributed output
to be concentrated.
Unfortunately, experiment shows that practical realization is very
difficult. In effect, it is very difficult to control the dimensions and
homogeneity of optical waveguides, and nobody has actually succeeded in
making a laser operate in this way, with a beam really possessing an
overall natural mode produced from the individual modes of the different
guides. A correct concentration of energy is therefore not obtained.
An attempt has been made to achieve this, for example with semiconductor
lasers, in which the emission of light is stimulated by the injection of
currents into the junctions. However, it is realised that the injection of
current alters the refractive indices in the guides. These changes in
index modify the phases of the optical waves. There is a failure to obtain
in the different guides a distribution of phases which would combine to
give a beam intensity distributed spatially in the desired manner.
SUMMARY OF THE INVENTION
The invention proposes a method of producing a laser operating on the
principle of multiple optical waveguide structures and having an intensity
distribution of desired output.
According to the invention, a laser is proposed comprising a plurality of
juxtaposed parallel optical waveguides having a mutual lateral optical
coupling between them, with means for individually controlling the
refractive index in the different guides or between the different guides.
Through this individual local control of the indices, it is possible to
control the relative phases of the optical wave in the different guides
and hence the overall distribution of light intensity at the output of the
coupled structure.
The preferred embodiment is as follows: the optical waveguides are made
from an electro-optical material and provision is made for control
electrodes placed in the vicinity of the guides in order to achieve
individual control of the refractive index in the guides, and for means of
applying individual potentials to these electrodes so as to adjust the
relative phases of the wave in the different guides. This adjustment of
phase is carried out through the intermediary of an adjustment of the
effective refractive index in a guide; the index of the guide depends on
the potential applied to an electrode placed near this guide because the
guide is made of an electro-optical material.
In this embodiment, the optical waveguides form an integral part of the
resonant cavity producing the laser effect. Plane mirrors or other means
of reflection are placed at the ends of the guides in order to form this
cavity.
It is possible in this way to produce a solid laser in a substrate on which
are formed optical waveguides made of a material capable of the emission
of stimulated light, provided that this material has electro-optical
properties, i.e. has in practice a controllable effective refractive
index.
Neodymium-doped lithium niobate (Nd: LiNbO.sub.3), for example, is a solid
material capable of being stimulated and in addition it is
electro-optical, i.e. its refractive index can be electrically controlled.
More generally, other materials with electro-optical properties can be used
if they enable optical waveguides to be produced and if they can be doped
in order to allow laser emission. This assumes, in general, that the
material is crystalline and transparent to the wavelength of the laser
transition and also transparent, when the emission is stimulated by a
pumping laser, to the wavelength of the pumping laser. Lithium tantalate
is an example of such a material.
In a particular embodiment, plane mirrors are arranged at the ends of the
guides in order to form a laser cavity. In another embodiment, the mirrors
are replaced by distributed Bragg lattices at the ends of the guides,
these lattices having the known property of reflecting electromagnetic
waves with a particular wavelength (equal to twice the lattice pitch
divided by the effective refractive index in the guides).
For exciting the laser, it is possible to use pumping laser diodes, either
individuals or coupled (multistrip laser diode). If separate individual
diodes are used, they will preferably be connected to the inputs of the
multiple guide laser structure of the invention through the intermediary
of an optical transfer system with optical waveguides.
In a variant of the embodiment, the guides of the multiple guide laser
structure do not all extend between the mirrors defining the laser cavity.
Even so, they are nevertheless all coupled to each other.
BRIEF DESCRIPTION OF THE DRAWINGS
Other characteristics and advantages of the invention will appear when
reading the detailed description which follows and which is given with
reference to the appended drawings in which:
FIG. 1 represents a multiple optical waveguide structure;
FIGS. 2a and 2b represent the configurations of the electric field at the
output of the structure of FIG. 1 for guides that are not coupled (2a) and
coupled (2b);
FIG. 3 represents a multiple guide laser structure according to the
invention;
FIGS. 4a and 4b represent some possible distributions of the electric field
at the output of the structure of FIG. 3.
FIG. 5 represents an embodiment with Bragg mirrors in distributed lattices;
FIG. 6 represents an embodiment with excitation by multistrip laser diode;
FIG. 7 represents an embodiment with excitation by individual laser diodes,
with an optical system for guided optical transfer;
FIG. 8 represents an embodiment with excitation by a single diode, with a
guided optical system using guides coupled between this diode and the
multiple guide laser structure of the invention;
FIG. 9 represents an embodiment of the multiple guide laser structure with
guides not extending between the two mirrors forming the laser cavity;
FIG. 10 represents another mode of embodiment of the invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 shows a crystalline substrate 10, for example made of lithium
niobate, in which juxtaposed optical waveguides 12 have been formed. These
guides are produced, for example, by doping longitudinal bands of small
width (of the order of the laser emission wavelength, for example of
several micrometers for a wavelength of about 1 micrometer). These
longitudinal bands, after doping (for example doping with titanium or by
proton exchange), have a refractive index n1 higher than the index n of
the crystal in which the bands are formed. They therefore form optical
waveguides. Their number may be from a few units to several tens or even
more.
Mirrors M1 and M2 are placed at the ends of the crystal, separated by a
multiple of the laser wavelength, these mirrors being reflecting for this
wavelength in order to create a laser cavity with a length from several
millimeters to several centimeters, for example.
The optical waveguides are doped, for example, with neodymium, so that they
can emit, and their emission is stimulated by a pumping laser LP placed
behind one of the mirrors (M2). This mirror M2 must be transparent at the
wavelength of the pumping laser, while it is reflecting for the light from
the neodymium laser. Such a structure in fact corresponds to a
multiplicity of individual lasers each consisting of one of the guides, of
the portions of the mirrors which enclose them and of a pumping laser or
an element of pumping laser emitting opposite this guide.
The distribution of the electric field at the output of this structure is
that shown in FIG. 2a in the case where the guides are not coupled
optically by evanescent waves (for example, because these guides are too
far away from each other); each guide propagates a wave with a natural
mode corresponding to this guide. The distribution of the field E and
hence the light intensity at the output is uniformly distributed between
the different guides. In a way, this amounts to a plurality of juxtaposed
laser beams but not to a single laser beam.
If now the longitudinal bands are brought closer together to a distance of
the order of the wavelength or several wavelengths, there is optical
coupling between the guides, i.e. the Maxwell's equations governing the
electric fields are no longer subject to the same boundary conditions.
There is interaction between the beams, the electromagnetic field is
propagated with a natural mode and the electric field E has a distribution
which is very different from the distribution of FIG. 2a. In an entirely
feasible theoretical configuration, the interactions between the optical
waves lead to the field configuration of FIG. 2b: the concentration of
energy is a maximum at the centre. The structure propagates the energy
according to a natural mode and not according to the simple juxtaposition
of the modes of the individual guides as in FIG. 2a. Everything happens as
if there were a single laser with a distribution of energy distributed
over a wide region, with a greater concentration at the centre.
However, this optimal configuration only really exists if the optical waves
propagating in each of the guides is correctly composed, and the key
factor which determines the composition of the electric fields due to two
coupled waves is the relative phase of the two waves.
If the structure with coupled guides were perfect, it would easily be
possible, by an appropriate choice of the dimensions and spacings of the
guides as a function of the refractive indices of the guides and the gaps
which separate them, to obtain a composed electric field having the
distribution of FIG. 2b.
However, technological limitations do not allow this to be achieved: there
are inaccuracies in the production of the desired dimensions and there are
inhomogeneities in the materials, the doping, etc, which lead to
unpredictable relative phase modifications in the propagated waves.
That is why the invention proposes a local and individual control of the
value of the refractive index of the different guides (or at least some of
them), given that a variation of the index leads to a phase modification
of the propagated wave.
FIG. 3 shows the preferred example of an embodiment, which involves placing
on each guide or in the immediate vicinity of this guide a control
electrode having an electro-optical effect, i.e. creating in the guide
(and only in this guide) a variation of the effective refractive index of
the propagation medium.
By applying a suitable potential to each electrode, it is possible to
adjust the phase of the propagated wave in the corresponding guide
relative to the phases in the other guides.
In this way, it is possible to rectify all the phase errors which would be
due to inhomogeneities in the optical waveguides or to inaccuracies in the
dimensions.
However, it is also possible to use these electrodes to configure the
electric field at the output of the structure in a way different from the
simplest configuration of FIG. 2b. In effect, the electrode potentials can
be used to give, for example, asymmetric electric field configurations
such as those of FIG. 4a or FIG. 4b.
In effect, as has been explained, the composition of the electric fields in
the coupled guides is directly related to the phases of the waves in the
individual guides and the phases are directly influenced by the potentials
applied to the electrodes because of the electro-optical properties of the
material forming the guides.
In this way, a very important application of the invention is obtained:
this is the achievement of a variable directivity of the laser beam, with
electrical control of this directivity; this directivity is obtained in
the very interior of the laser and not by an optical component placed
downstream from the laser.
In the case of FIG. 4a, the electric field configuration corresponds
directly to a laser beam with energy distributed according to a lobe whose
general orientation has an axis offset to the left with respect to the
axis of the parallel optical waveguides. In the case of FIG. 4b, the beam
is directional and oriented towards the right.
With a variable configuration of potentials, it is possible, if so desired,
to achieve the equivalent of a scanning of the laser beam, the direction
of maximum beam intensity varying with the applied potentials; this
scanning is similar to electronic scanning in radar aerials, in which a
scanning of emission directivity is achieved by suitable phase differences
between the frequencies emitted by elementary aerials close to each other.
The asymmetric configuration of the electric field in the immediate
vicinity of the output from the guides of the structure in effect
corresponds to a farfield directional radiation pattern with a lobe which
is offset with respect to the axis.
The electrodes 14 intended to modify the respective individual phases of
propagation in the different guides 12 may be arranged either just above
the guides or between the guides.
In order to produce the laser cavity in the multiple optical waveguide
structure according to the invention, there are several methods. One
method is the use of mirrors placed at the ends of the guides, separated
by a multiple of the laser emission wavelength (about 1.084 micrometers
for a neodymium laser). The mirrors may be added or deposited directly on
the ends of the structure.
The mirror M2 is characterised by a high transmission coefficient at the
wavelength of the pumping laser LP, whereas it has a maximum reflection
coefficient at the wavelength of the laser emission. The mirror M1 has a
reflection coefficient adjusted as a function of the magnitude of the
magnification factor desired for the cavity, taking into account the gain
and the losses of the said cavity.
Another way of producing the laser cavity is to replace the mirrors by
distributed lattices deposited on the structure and having the same
function as the mirrors, i.e. capable of sending back an electromagnetic
wave of given wavelength. FIG. 5 shows in diagrammatic form the use of
such lattices 16 and 18 at each end of the structure; the pitch p of the
lattice is chosen equal to the product of the wavelength lambda of the
light to be reflected times half the effective refractive index n.sub.eff
in the structure for its natural mode at the wavelength in question. The
electrodes 14 making it possible to modify the natural mode of propagation
are placed along the guides between the lattices 16 and 18.
Pumping of the structure is preferably achieved by means of a laser diode
or a set of laser diodes. The emission wavelength of the pumping diodes is
in resonance with the absorption band of the rare earth ion used (e.g.
0.814 micrometers for neodymium in the Nd.sup.3+ form inserted in lithium
niobate). In order to obtain this precise wavelength in the pumping laser
diodes, the compositions and thicknesses of the semiconductor layers based
on gallium-aluminium arsenide composing the diodes are controlled. It is
also possible to use laser diodes with multiple quantum wells.
The coupling of the pumping wave to the multiple guide structure can be
achieved in various ways. The first involves the use of a multistrip laser
diode in which the dimension of the natural mode is best matched to that
of the natural mode of the multiple guide structure at the pumping
wavelength. An optical coupling system can be used at the pumping
wavelength for matching these two modes. Such a multistrip diode structure
20 is represented in FIG. 6. The electrodes of the multiple guide
structure are not shown in this figure for reasons of simplicity.
A second method relies on the use of an optical transfer system (FIG. 7)
connecting the pumping laser diodes 22 (separated laterally and hence not
coupled together) or of a multistrip laser diode at the input of the
multiple guide laser structure of the invention. This optical transfer
system consists of optical waveguides 24 which, in their upstream part 24b
(on the side of the laser diodes 22 or of the multistrip laser diode), are
opposite the pumping laser diodes 22 and which get closer together (FIG.
7) or further apart until they are opposite the optical waveguides 12
carried by the substrate 10 in their oval part 24a (on the side of the
multiple guide structure according to the invention). The pumping laser
light emerges from the diodes 22 and passing through the guides 24 passes
through the mirror M2 and comes to excite the rare earth doping of the
guides 12 of the laser structure according to the invention. This method
is suitable when the pumping wave is made up of a set of light sources
independent from each other or of a multistrip diode whose natural mode is
different from that of the multiple guide laser structure at the pumping
wavelength. The natural mode at the output from the optical transfer
system with guides 24 is preferably chosen to be the same as the natural
mode of the laser guide 10, 12 at the pumping wavelength. The electrodes
14 are not represented in FIG. 7.
A third method (FIG. 8) involves the use of an integrated optical transfer
system with guides coupled between an individual laser diode 26 and the
multiple guide structure of the invention. The single laser diode emits a
pumping laser beam towards one end of a first guide 28 whose other end is
coupled laterally to other guides 30, which themselves are coupled
laterally to other guides 32, and so on. By mutual coupling, the injected
energy is distributed between these different guides which together form
the equivalent of an integrated optical lens; the outputs from these
guides 30, 32, etc, are arranged opposite the inputs to the guides of the
multiple guide laser structure of the invention. Here again, the phase
control electrodes 14 used to establish the desired mode of propagation
are not represented.
In yet another embodiment, represented in FIG. 9, the coupled multiple
guide laser structure with a propagation supermode consists of guides
whose lengths are less than the distance separating the mirrors M1 and M2
which define the laser cavity. Some of the guides reach the immediate
vicinity of the mirror M2 in order to receive the pumping laser wave (e.g.
guide 36 in FIG. 9) but do not extend as far as the other mirror. Other
guides, such as 38, extend to the vicinity of the mirror M1 on the output
side of the structure, but do not extend as far as the input mirror M2.
The guides 36 and the guides 38 are coupled to each other and the
successive coupled guides extending between the two mirrors form cavities
in which laser resonance can occur. Electrodes are used here once again to
modify the phases in order to adjust the laser propagation supermode of
the structure.
In yet another embodiment, represented in FIG. 10, the coupled multiple
guide laser structure consists of guides whose lengths are less than the
distance separating the mirrors M1 and M2 which define the laser cavity.
In this embodiment, all the guides reach the immediate vicinity of the
mirror M2 in order to receive the pumping laser wave, but do not extend as
far as the other mirror except for one of the guides (preferably the
central guide). The length of each guide is chosen in such a way that,
from an equal distribution of energy in the guides at the level of the
mirror M2 and at the laser wavelength, maximum energy is retrieved in the
central guide extending as far as the mirror M1. The energy is distributed
by mutual coupling between the guides, which form the equivalent of an
integrated optical lens. Electrodes are used here once again to modify the
phases in order to optimise the progressive transfer of the energy to the
central guide.
This device makes it possible to increase the available power in a
single-mode laser guide thanks to the increase in the number of pumping
sources. This is of particular interest if it is desired to couple the
output from the laser (at the level of the mirror M1) to a single-mode
optical fibre or if it is desired to double the frequency (generation of
green radiation at 0.54 .mu.m in the case of the laser material
Nd:LiNbO.sub.3 emitting at 1.084 .mu.m) the laser energy being propagated
in the central guide.
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